startop/scripts/app_startup/app_startup_runner.py - platform/frameworks/base - Git at Google

 #!/usr/bin/env python3
 #
 # Copyright 2018, The Android Open Source Project
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     http://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.

 #
 #
 # Measure application start-up time by launching applications under various combinations.
 # See --help for more details.
 #
 #
 # Sample usage:
 # $> ./app_startup_runner.py -p com.google.android.calculator -r warm -r cold -lc 10  -o out.csv
 # $> ./analyze_metrics.py out.csv
 #
 #

 import argparse
 import csv
 import itertools
 import os
 import subprocess
 import sys
 import tempfile
 from typing import Any, Callable, Dict, Generic, Iterable, List, NamedTuple, TextIO, Tuple, TypeVar, Optional, Union

 # The following command line options participate in the combinatorial generation.
 # All other arguments have a global effect.
 _COMBINATORIAL_OPTIONS=['packages', 'readaheads', 'compiler_filters']
 _TRACING_READAHEADS=['mlock', 'fadvise']
 _FORWARD_OPTIONS={'loop_count': '--count'}
 _RUN_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'run_app_with_prefetch')

 RunCommandArgs = NamedTuple('RunCommandArgs', [('package', str), ('readahead', str), ('compiler_filter', Optional[str])])
 CollectorPackageInfo = NamedTuple('CollectorPackageInfo', [('package', str), ('compiler_filter', str)])
 _COLLECTOR_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'collector')
 _COLLECTOR_TIMEOUT_MULTIPLIER = 2 # take the regular --timeout and multiply by 2; systrace starts up slowly.

 _UNLOCK_SCREEN_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'unlock_screen')

 # This must be the only mutable global variable. All other global variables are constants to avoid magic literals.
 _debug = False  # See -d/--debug flag.
 _DEBUG_FORCE = None  # Ignore -d/--debug if this is not none.

 # Type hinting names.
 T = TypeVar('T')
 NamedTupleMeta = Callable[..., T]  # approximation of a (S : NamedTuple<T> where S() == T) metatype.

 def parse_options(argv: List[str] = None):
   """Parse command line arguments and return an argparse Namespace object."""
   parser = argparse.ArgumentParser(description="Run one or more Android applications under various settings in order to measure startup time.")
   # argparse considers args starting with - and -- optional in --help, even though required=True.
   # by using a named argument group --help will clearly say that it's required instead of optional.
   required_named = parser.add_argument_group('required named arguments')
   required_named.add_argument('-p', '--package', action='append', dest='packages', help='package of the application', required=True)
   required_named.add_argument('-r', '--readahead', action='append', dest='readaheads', help='which readahead mode to use', choices=('warm', 'cold', 'mlock', 'fadvise'), required=True)

   # optional arguments
   # use a group here to get the required arguments to appear 'above' the optional arguments in help.
   optional_named = parser.add_argument_group('optional named arguments')
   optional_named.add_argument('-c', '--compiler-filter', action='append', dest='compiler_filters', help='which compiler filter to use. if omitted it does not enforce the app\'s compiler filter', choices=('speed', 'speed-profile', 'quicken'))
   optional_named.add_argument('-s', '--simulate', dest='simulate', action='store_true', help='Print which commands will run, but don\'t run the apps')
   optional_named.add_argument('-d', '--debug', dest='debug', action='store_true', help='Add extra debugging output')
   optional_named.add_argument('-o', '--output', dest='output', action='store', help='Write CSV output to file.')
   optional_named.add_argument('-t', '--timeout', dest='timeout', action='store', type=int, help='Timeout after this many seconds when executing a single run.')
   optional_named.add_argument('-lc', '--loop-count', dest='loop_count', default=1, type=int, action='store', help='How many times to loop a single run.')
   optional_named.add_argument('-in', '--inodes', dest='inodes', type=str, action='store', help='Path to inodes file (system/extras/pagecache/pagecache.py -d inodes)')

   return parser.parse_args(argv)

 # TODO: refactor this with a common library file with analyze_metrics.py
 def _debug_print(*args, **kwargs):
   """Print the args to sys.stderr if the --debug/-d flag was passed in."""
   if _debug:
     print(*args, **kwargs, file=sys.stderr)

 def _expand_gen_repr(args):
   """Like repr but any generator-like object has its iterator consumed
   and then called repr on."""
   new_args_list = []
   for i in args:
     # detect iterable objects that do not have their own override of __str__
     if hasattr(i, '__iter__'):
       to_str = getattr(i, '__str__')
       if to_str.__objclass__ == object:
         # the repr for a generator is just type+address, expand it out instead.
         new_args_list.append([_expand_gen_repr([j])[0] for j in i])
         continue
     # normal case: uses the built-in to-string
     new_args_list.append(i)
   return new_args_list

 def _debug_print_gen(*args, **kwargs):
   """Like _debug_print but will turn any iterable args into a list."""
   if not _debug:
     return

   new_args_list = _expand_gen_repr(args)
   _debug_print(*new_args_list, **kwargs)

 def _debug_print_nd(*args, **kwargs):
   """Like _debug_print but will turn any NamedTuple-type args into a string."""
   if not _debug:
     return

   new_args_list = []
   for i in args:
     if hasattr(i, '_field_types'):
       new_args_list.append("%s: %s" %(i.__name__, i._field_types))
     else:
       new_args_list.append(i)

   _debug_print(*new_args_list, **kwargs)

 def dict_lookup_any_key(dictionary: dict, *keys: List[Any]):
   for k in keys:
     if k in dictionary:
       return dictionary[k]
   raise KeyError("None of the keys %s were in the dictionary" %(keys))

 def generate_run_combinations(named_tuple: NamedTupleMeta[T], opts_dict: Dict[str, List[Optional[str]]])\
     -> Iterable[T]:
   """
   Create all possible combinations given the values in opts_dict[named_tuple._fields].

   :type T: type annotation for the named_tuple type.
   :param named_tuple: named tuple type, whose fields are used to make combinations for
   :param opts_dict: dictionary of keys to value list. keys correspond to the named_tuple fields.
   :return: an iterable over named_tuple instances.
   """
   combinations_list = []
   for k in named_tuple._fields:
     # the key can be either singular or plural , e.g. 'package' or 'packages'
     val = dict_lookup_any_key(opts_dict, k, k + "s")

     # treat {'x': None} key value pairs as if it was [None]
     # otherwise itertools.product throws an exception about not being able to iterate None.
     combinations_list.append(val or [None])

   _debug_print("opts_dict: ", opts_dict)
   _debug_print_nd("named_tuple: ", named_tuple)
   _debug_print("combinations_list: ", combinations_list)

   for combo in itertools.product(*combinations_list):
     yield named_tuple(*combo)

 def key_to_cmdline_flag(key: str) -> str:
   """Convert key into a command line flag, e.g. 'foo-bars' -> '--foo-bar' """
   if key.endswith("s"):
     key = key[:-1]
   return "--" + key.replace("_", "-")

 def as_run_command(tpl: NamedTuple) -> List[Union[str, Any]]:
   """
   Convert a named tuple into a command-line compatible arguments list.

   Example: ABC(1, 2, 3) -> ['--a', 1, '--b', 2, '--c', 3]
   """
   args = []
   for key, value in tpl._asdict().items():
     if value is None:
       continue
     args.append(key_to_cmdline_flag(key))
     args.append(value)
   return args

 def generate_group_run_combinations(run_combinations: Iterable[NamedTuple], dst_nt: NamedTupleMeta[T])\
     -> Iterable[Tuple[T, Iterable[NamedTuple]]]:

   def group_by_keys(src_nt):
     src_d = src_nt._asdict()
     # now remove the keys that aren't legal in dst.
     for illegal_key in set(src_d.keys()) - set(dst_nt._fields):
       if illegal_key in src_d:
         del src_d[illegal_key]

     return dst_nt(**src_d)

   for args_list_it in itertools.groupby(run_combinations, group_by_keys):
     (group_key_value, args_it) = args_list_it
     yield (group_key_value, args_it)

 def parse_run_script_csv_file(csv_file: TextIO) -> List[int]:
   """Parse a CSV file full of integers into a flat int list."""
   csv_reader = csv.reader(csv_file)
   arr = []
   for row in csv_reader:
     for i in row:
       if i:
         arr.append(int(i))
   return arr

 def make_script_command_with_temp_output(script: str, args: List[str], **kwargs)\
     -> Tuple[str, TextIO]:
   """
   Create a command to run a script given the args.
   Appends --count <loop_count> --output <tmp-file-name>.
   Returns a tuple (cmd, tmp_file)
   """
   tmp_output_file = tempfile.NamedTemporaryFile(mode='r')
   cmd = [script] + args
   for key, value in kwargs.items():
     cmd += ['--%s' %(key), "%s" %(value)]
   if _debug:
     cmd += ['--verbose']
   cmd = cmd + ["--output", tmp_output_file.name]
   return cmd, tmp_output_file

 def execute_arbitrary_command(cmd: List[str], simulate: bool, timeout: int) -> Tuple[bool, str]:
   if simulate:
     print(" ".join(cmd))
     return (True, "")
   else:
     _debug_print("[EXECUTE]", cmd)
     proc = subprocess.Popen(cmd,
                             stderr=subprocess.STDOUT,
                             stdout=subprocess.PIPE,
                             universal_newlines=True)
     try:
       script_output = proc.communicate(timeout=timeout)[0]
     except subprocess.TimeoutExpired:
       print("[TIMEDOUT]")
       proc.kill()
       script_output = proc.communicate()[0]

     _debug_print("[STDOUT]", script_output)
     return_code = proc.wait()
     passed = (return_code == 0)
     _debug_print("[$?]", return_code)
     if not passed:
       print("[FAILED, code:%s]" %(return_code), script_output, file=sys.stderr)

     return (passed, script_output)

 def execute_run_combos(grouped_run_combos: Iterable[Tuple[CollectorPackageInfo, Iterable[RunCommandArgs]]], simulate: bool, inodes_path: str, timeout: int, loop_count: int, need_trace: bool):
   # nothing will work if the screen isn't unlocked first.
   execute_arbitrary_command([_UNLOCK_SCREEN_SCRIPT], simulate, timeout)

   for collector_info, run_combos in grouped_run_combos:
     #collector_args = ["--package", package_name]
     collector_args = as_run_command(collector_info)
     # TODO: forward --wait_time for how long systrace runs?
     # TODO: forward --trace_buffer_size for size of systrace buffer size?
     collector_cmd, collector_tmp_output_file = make_script_command_with_temp_output(_COLLECTOR_SCRIPT, collector_args, inodes=inodes_path)

     with collector_tmp_output_file:
       collector_passed = True
       if need_trace:
         collector_timeout = timeout and _COLLECTOR_TIMEOUT_MULTIPLIER * timeout
         (collector_passed, collector_script_output) = execute_arbitrary_command(collector_cmd, simulate, collector_timeout)
         # TODO: consider to print a ; collector wrote file to <...> into the CSV file so we know it was ran.

       for combos in run_combos:
         args = as_run_command(combos)

         cmd, tmp_output_file = make_script_command_with_temp_output(_RUN_SCRIPT, args, count=loop_count, input=collector_tmp_output_file.name)
         with tmp_output_file:
           (passed, script_output) = execute_arbitrary_command(cmd, simulate, timeout)
           parsed_output = simulate and [1,2,3] or parse_run_script_csv_file(tmp_output_file)
           yield (passed, script_output, parsed_output)

 def gather_results(commands: Iterable[Tuple[bool, str, List[int]]], key_list: List[str], value_list: List[Tuple[str, ...]]):
   _debug_print("gather_results: key_list = ", key_list)
   yield key_list + ["time(ms)"]

   stringify_none = lambda s: s is None and "<none>" or s

   for ((passed, script_output, run_result_list), values) in itertools.zip_longest(commands, value_list):
     if not passed:
       continue
     for result in run_result_list:
       yield [stringify_none(i) for i in values] + [result]

     yield ["; avg(%s), min(%s), max(%s), count(%s)" %(sum(run_result_list, 0.0) / len(run_result_list), min(run_result_list), max(run_result_list), len(run_result_list)) ]

 def eval_and_save_to_csv(output, annotated_result_values):
   csv_writer = csv.writer(output)
   for row in annotated_result_values:
     csv_writer.writerow(row)
     output.flush() # see the output live.

 def main():
   global _debug

   opts = parse_options()
   _debug = opts.debug
   if _DEBUG_FORCE is not None:
     _debug = _DEBUG_FORCE
   _debug_print("parsed options: ", opts)
   need_trace = not not set(opts.readaheads).intersection(set(_TRACING_READAHEADS))
   if need_trace and not opts.inodes:
     print("Error: Missing -in/--inodes, required when using a readahead of %s" %(_TRACING_READAHEADS), file=sys.stderr)
     return 1

   output_file = opts.output and open(opts.output, 'w') or sys.stdout

   combos = lambda: generate_run_combinations(RunCommandArgs, vars(opts))
   _debug_print_gen("run combinations: ", combos())

   grouped_combos = lambda: generate_group_run_combinations(combos(), CollectorPackageInfo)
   _debug_print_gen("grouped run combinations: ", grouped_combos())

   exec = execute_run_combos(grouped_combos(), opts.simulate, opts.inodes, opts.timeout, opts.loop_count, need_trace)
   results = gather_results(exec, _COMBINATORIAL_OPTIONS, combos())
   eval_and_save_to_csv(output_file, results)

   return 0


 if __name__ == '__main__':
   sys.exit(main())
	#!/usr/bin/env python3
	#
	# Copyright 2018, The Android Open Source Project
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	#
	#
	# Measure application start-up time by launching applications under various combinations.
	# See --help for more details.
	#
	#
	# Sample usage:
	# $> ./app_startup_runner.py -p com.google.android.calculator -r warm -r cold -lc 10 -o out.csv
	# $> ./analyze_metrics.py out.csv
	#
	#

	import argparse
	import csv
	import itertools
	import os
	import subprocess
	import sys
	import tempfile
	from typing import Any, Callable, Dict, Generic, Iterable, List, NamedTuple, TextIO, Tuple, TypeVar, Optional, Union

	# The following command line options participate in the combinatorial generation.
	# All other arguments have a global effect.
	_COMBINATORIAL_OPTIONS=['packages', 'readaheads', 'compiler_filters']
	_TRACING_READAHEADS=['mlock', 'fadvise']
	_FORWARD_OPTIONS={'loop_count': '--count'}
	_RUN_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'run_app_with_prefetch')

	RunCommandArgs = NamedTuple('RunCommandArgs', [('package', str), ('readahead', str), ('compiler_filter', Optional[str])])
	CollectorPackageInfo = NamedTuple('CollectorPackageInfo', [('package', str), ('compiler_filter', str)])
	_COLLECTOR_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'collector')
	_COLLECTOR_TIMEOUT_MULTIPLIER = 2 # take the regular --timeout and multiply by 2; systrace starts up slowly.

	_UNLOCK_SCREEN_SCRIPT=os.path.join(os.path.dirname(os.path.realpath(__file__)), 'unlock_screen')

	# This must be the only mutable global variable. All other global variables are constants to avoid magic literals.
	_debug = False # See -d/--debug flag.
	_DEBUG_FORCE = None # Ignore -d/--debug if this is not none.

	# Type hinting names.
	T = TypeVar('T')
	NamedTupleMeta = Callable[..., T] # approximation of a (S : NamedTuple<T> where S() == T) metatype.

	def parse_options(argv: List[str] = None):
	"""Parse command line arguments and return an argparse Namespace object."""
	parser = argparse.ArgumentParser(description="Run one or more Android applications under various settings in order to measure startup time.")
	# argparse considers args starting with - and -- optional in --help, even though required=True.
	# by using a named argument group --help will clearly say that it's required instead of optional.
	required_named = parser.add_argument_group('required named arguments')
	required_named.add_argument('-p', '--package', action='append', dest='packages', help='package of the application', required=True)
	required_named.add_argument('-r', '--readahead', action='append', dest='readaheads', help='which readahead mode to use', choices=('warm', 'cold', 'mlock', 'fadvise'), required=True)

	# optional arguments
	# use a group here to get the required arguments to appear 'above' the optional arguments in help.
	optional_named = parser.add_argument_group('optional named arguments')
	optional_named.add_argument('-c', '--compiler-filter', action='append', dest='compiler_filters', help='which compiler filter to use. if omitted it does not enforce the app\'s compiler filter', choices=('speed', 'speed-profile', 'quicken'))
	optional_named.add_argument('-s', '--simulate', dest='simulate', action='store_true', help='Print which commands will run, but don\'t run the apps')
	optional_named.add_argument('-d', '--debug', dest='debug', action='store_true', help='Add extra debugging output')
	optional_named.add_argument('-o', '--output', dest='output', action='store', help='Write CSV output to file.')
	optional_named.add_argument('-t', '--timeout', dest='timeout', action='store', type=int, help='Timeout after this many seconds when executing a single run.')
	optional_named.add_argument('-lc', '--loop-count', dest='loop_count', default=1, type=int, action='store', help='How many times to loop a single run.')
	optional_named.add_argument('-in', '--inodes', dest='inodes', type=str, action='store', help='Path to inodes file (system/extras/pagecache/pagecache.py -d inodes)')

	return parser.parse_args(argv)

	# TODO: refactor this with a common library file with analyze_metrics.py
	def _debug_print(args, *kwargs):
	"""Print the args to sys.stderr if the --debug/-d flag was passed in."""
	if _debug:
	print(args, *kwargs, file=sys.stderr)

	def _expand_gen_repr(args):
	"""Like repr but any generator-like object has its iterator consumed
	and then called repr on."""
	new_args_list = []
	for i in args:
	# detect iterable objects that do not have their own override of __str__
	if hasattr(i, '__iter__'):
	to_str = getattr(i, '__str__')
	if to_str.__objclass__ == object:
	# the repr for a generator is just type+address, expand it out instead.
	new_args_list.append([_expand_gen_repr([j])[0] for j in i])
	continue
	# normal case: uses the built-in to-string
	new_args_list.append(i)
	return new_args_list

	def _debug_print_gen(args, *kwargs):
	"""Like _debug_print but will turn any iterable args into a list."""
	if not _debug:
	return

	new_args_list = _expand_gen_repr(args)
	_debug_print(new_args_list, *kwargs)

	def _debug_print_nd(args, *kwargs):
	"""Like _debug_print but will turn any NamedTuple-type args into a string."""
	if not _debug:
	return

	new_args_list = []
	for i in args:
	if hasattr(i, '_field_types'):
	new_args_list.append("%s: %s" %(i.__name__, i._field_types))
	else:
	new_args_list.append(i)

	_debug_print(new_args_list, *kwargs)

	def dict_lookup_any_key(dictionary: dict, *keys: List[Any]):
	for k in keys:
	if k in dictionary:
	return dictionary[k]
	raise KeyError("None of the keys %s were in the dictionary" %(keys))

	def generate_run_combinations(named_tuple: NamedTupleMeta[T], opts_dict: Dict[str, List[Optional[str]]])\
	-> Iterable[T]:
	"""
	Create all possible combinations given the values in opts_dict[named_tuple._fields].

	:type T: type annotation for the named_tuple type.
	:param named_tuple: named tuple type, whose fields are used to make combinations for
	:param opts_dict: dictionary of keys to value list. keys correspond to the named_tuple fields.
	:return: an iterable over named_tuple instances.
	"""
	combinations_list = []
	for k in named_tuple._fields:
	# the key can be either singular or plural , e.g. 'package' or 'packages'
	val = dict_lookup_any_key(opts_dict, k, k + "s")

	# treat {'x': None} key value pairs as if it was [None]
	# otherwise itertools.product throws an exception about not being able to iterate None.
	combinations_list.append(val or [None])

	_debug_print("opts_dict: ", opts_dict)
	_debug_print_nd("named_tuple: ", named_tuple)
	_debug_print("combinations_list: ", combinations_list)

	for combo in itertools.product(*combinations_list):
	yield named_tuple(*combo)

	def key_to_cmdline_flag(key: str) -> str:
	"""Convert key into a command line flag, e.g. 'foo-bars' -> '--foo-bar' """
	if key.endswith("s"):
	key = key[:-1]
	return "--" + key.replace("_", "-")

	def as_run_command(tpl: NamedTuple) -> List[Union[str, Any]]:
	"""
	Convert a named tuple into a command-line compatible arguments list.

	Example: ABC(1, 2, 3) -> ['--a', 1, '--b', 2, '--c', 3]
	"""
	args = []
	for key, value in tpl._asdict().items():
	if value is None:
	continue
	args.append(key_to_cmdline_flag(key))
	args.append(value)
	return args

	def generate_group_run_combinations(run_combinations: Iterable[NamedTuple], dst_nt: NamedTupleMeta[T])\
	-> Iterable[Tuple[T, Iterable[NamedTuple]]]:

	def group_by_keys(src_nt):
	src_d = src_nt._asdict()
	# now remove the keys that aren't legal in dst.
	for illegal_key in set(src_d.keys()) - set(dst_nt._fields):
	if illegal_key in src_d:
	del src_d[illegal_key]

	return dst_nt(**src_d)

	for args_list_it in itertools.groupby(run_combinations, group_by_keys):
	(group_key_value, args_it) = args_list_it
	yield (group_key_value, args_it)

	def parse_run_script_csv_file(csv_file: TextIO) -> List[int]:
	"""Parse a CSV file full of integers into a flat int list."""
	csv_reader = csv.reader(csv_file)
	arr = []
	for row in csv_reader:
	for i in row:
	if i:
	arr.append(int(i))
	return arr

	def make_script_command_with_temp_output(script: str, args: List[str], **kwargs)\
	-> Tuple[str, TextIO]:
	"""
	Create a command to run a script given the args.
	Appends --count <loop_count> --output <tmp-file-name>.
	Returns a tuple (cmd, tmp_file)
	"""
	tmp_output_file = tempfile.NamedTemporaryFile(mode='r')
	cmd = [script] + args
	for key, value in kwargs.items():
	cmd += ['--%s' %(key), "%s" %(value)]
	if _debug:
	cmd += ['--verbose']
	cmd = cmd + ["--output", tmp_output_file.name]
	return cmd, tmp_output_file

	def execute_arbitrary_command(cmd: List[str], simulate: bool, timeout: int) -> Tuple[bool, str]:
	if simulate:
	print(" ".join(cmd))
	return (True, "")
	else:
	_debug_print("[EXECUTE]", cmd)
	proc = subprocess.Popen(cmd,
	stderr=subprocess.STDOUT,
	stdout=subprocess.PIPE,
	universal_newlines=True)
	try:
	script_output = proc.communicate(timeout=timeout)[0]
	except subprocess.TimeoutExpired:
	print("[TIMEDOUT]")
	proc.kill()
	script_output = proc.communicate()[0]

	_debug_print("[STDOUT]", script_output)
	return_code = proc.wait()
	passed = (return_code == 0)
	_debug_print("[$?]", return_code)
	if not passed:
	print("[FAILED, code:%s]" %(return_code), script_output, file=sys.stderr)

	return (passed, script_output)

	def execute_run_combos(grouped_run_combos: Iterable[Tuple[CollectorPackageInfo, Iterable[RunCommandArgs]]], simulate: bool, inodes_path: str, timeout: int, loop_count: int, need_trace: bool):
	# nothing will work if the screen isn't unlocked first.
	execute_arbitrary_command([_UNLOCK_SCREEN_SCRIPT], simulate, timeout)

	for collector_info, run_combos in grouped_run_combos:
	#collector_args = ["--package", package_name]
	collector_args = as_run_command(collector_info)
	# TODO: forward --wait_time for how long systrace runs?
	# TODO: forward --trace_buffer_size for size of systrace buffer size?
	collector_cmd, collector_tmp_output_file = make_script_command_with_temp_output(_COLLECTOR_SCRIPT, collector_args, inodes=inodes_path)

	with collector_tmp_output_file:
	collector_passed = True
	if need_trace:
	collector_timeout = timeout and _COLLECTOR_TIMEOUT_MULTIPLIER * timeout
	(collector_passed, collector_script_output) = execute_arbitrary_command(collector_cmd, simulate, collector_timeout)
	# TODO: consider to print a ; collector wrote file to <...> into the CSV file so we know it was ran.

	for combos in run_combos:
	args = as_run_command(combos)

	cmd, tmp_output_file = make_script_command_with_temp_output(_RUN_SCRIPT, args, count=loop_count, input=collector_tmp_output_file.name)
	with tmp_output_file:
	(passed, script_output) = execute_arbitrary_command(cmd, simulate, timeout)
	parsed_output = simulate and [1,2,3] or parse_run_script_csv_file(tmp_output_file)
	yield (passed, script_output, parsed_output)

	def gather_results(commands: Iterable[Tuple[bool, str, List[int]]], key_list: List[str], value_list: List[Tuple[str, ...]]):
	_debug_print("gather_results: key_list = ", key_list)
	yield key_list + ["time(ms)"]

	stringify_none = lambda s: s is None and "<none>" or s

	for ((passed, script_output, run_result_list), values) in itertools.zip_longest(commands, value_list):
	if not passed:
	continue
	for result in run_result_list:
	yield [stringify_none(i) for i in values] + [result]

	yield ["; avg(%s), min(%s), max(%s), count(%s)" %(sum(run_result_list, 0.0) / len(run_result_list), min(run_result_list), max(run_result_list), len(run_result_list)) ]

	def eval_and_save_to_csv(output, annotated_result_values):
	csv_writer = csv.writer(output)
	for row in annotated_result_values:
	csv_writer.writerow(row)
	output.flush() # see the output live.

	def main():
	global _debug

	opts = parse_options()
	_debug = opts.debug
	if _DEBUG_FORCE is not None:
	_debug = _DEBUG_FORCE
	_debug_print("parsed options: ", opts)
	need_trace = not not set(opts.readaheads).intersection(set(_TRACING_READAHEADS))
	if need_trace and not opts.inodes:
	print("Error: Missing -in/--inodes, required when using a readahead of %s" %(_TRACING_READAHEADS), file=sys.stderr)
	return 1

	output_file = opts.output and open(opts.output, 'w') or sys.stdout

	combos = lambda: generate_run_combinations(RunCommandArgs, vars(opts))
	_debug_print_gen("run combinations: ", combos())

	grouped_combos = lambda: generate_group_run_combinations(combos(), CollectorPackageInfo)
	_debug_print_gen("grouped run combinations: ", grouped_combos())

	exec = execute_run_combos(grouped_combos(), opts.simulate, opts.inodes, opts.timeout, opts.loop_count, need_trace)
	results = gather_results(exec, _COMBINATORIAL_OPTIONS, combos())
	eval_and_save_to_csv(output_file, results)

	return 0


	if __name__ == '__main__':
	sys.exit(main())